DE3222307A1 - Lattice girder - Google Patents

Abstract

The invention relates to a lattice girder, in particular a lightweight lattice girder, having upper and lower booms which are connected to one another via strutting. It is precisely in lightweight lattice girders that the buckling length of each strut in the strutting is often relatively large, so that the buckling strength of the struts is low. The object is to construct a lattice girder of this type in such a way that the buckling length of the struts in the strutting is reduced and hence their buckling strength is increased in a simple manner. This is achieved according to the invention by a tension element running through in the girder longitudinal direction and anchored in a tension-proof manner at both ends, said tension element being supported at the points of intersection with the struts in a force-transmitting manner on the latter.

Description

The invention relates to a truss in the upper

term of claim 1 specified type.

From DE-OS 28 01 945 units for standard bridges are from Known steel, each consisting of a belt rod and a V-shaped rod arranged on it Striving exist. Any desired girders or bridges can be made from these structural units Put length and height together. In one embodiment, it is used to reduce suggested the buckling length of the struts, an additional one in each triangular connection Use a triangle made up of three shorter individual struts, with which the buckling length of the two struts is halved. The structural effort is extremely large here, because a smaller triangle must be incorporated into each triangle. In the case of a lightweight construction, it will be in this way in addition to the high construction Effort also result in too high a weight.

It is also known from practice to involve trusses X-shaped crossed struts in the strut system, the crossing points as nodes and, if necessary, a continuous, further belt parallel to the upper and lower belt Provide belt in the area of the nodes in the intersections with these connected is.

The buckling length of each strut is halved, but it is the structural effort for the formation of the nodes and the material costs extraordinarily large for the additional central belt.

The invention is based on the object of a truss To create the type mentioned at the beginning, in which on structurally and technically in a simple way, the buckling length of the struts in the strut composite is reduced and with their buckling resistance is increased.

The object set is according to the invention by the in the characterizing Part of claim 1 specified features solved.

In this design, the tension element divides the buckling length of each strut, each strut in the direction of the tension element in the crossing point to both Pages is prevented from buckling. Because the tension element is tensile at both ends is anchored, it acts like a tensile and compression-resistant element for each strut. Included are not the crossing point between each strut and the tension element in the manner of a usual knot, point, but it is only the tension element supported on the strut so that it can no longer buckle.

An expedient embodiment of the invention is based on claim 2 emerged. The manufacturing and structural effort for the formation of the crossing points is minimal.

Nevertheless, it is ensured that the buckling strength of each strut is increased. Each strut is connected to the two via its welding point on the tension element adjacent struts connected to transmit tensile force. This support is also at given the last struts within the longitudinal extent of the tension element, there the ends of the tension element are also anchored in a tensile manner.

The measure specified in claim 3 is also important here. at this formation of the anchoring of the ends of the tension element is ensured, that occurring tensile loads can be absorbed properly. The upper and lower chords are so stable that they can take these additional loads easily cope with.

Depending on the course of the struts in the strut mechanism, a alternative form of anchoring for the ends of the tension element can be selected, such as it emerges from claim 4.

An embodiment as explained in claim 5 is also expedient. Here, each tension element is only one behind the other for a certain number Striving in the striving responsible. This type of attachment of the tension element is chosen especially for longer trusses.

In practice it has proven to be useful if the feature of claim 6 is realized. Such a full profile can easily be a round bar, be a square bar or a strip of steel for the total weight of the truss result in only an insignificant additional burden. But hollow profiles can also do just as well can be used with any cross-sectional shape.

A particularly simple embodiment of a truss according to FIG of the invention claims 7. The passages are simple holes through which the tension element is inserted. It may be sufficient to drill the holes in the width to match the outer diameter of the tension element so that this without significant game is kept in it. As soon as the strut is under a Tries to deform buckling loads, a force-transmitting interlocking effect arises between the tension element and the bore of the strut, causing it to deform is prevented by buckling. It is more useful, however, the tension element in the To tie up passages so that any relative movement of the strut towards it (Ifem / ue ^ element is suppressed.

An alternative embodiment emerges from claim 8. To shorten it the buckling length and to increase the buckling strength of the struts, it is sufficient if the Zugelemat is only welded to the outside of the strut is.

A further, improved embodiment, however, is based on the claim 9, in which a tension element is welded onto both sides of the struts is. It is obvious that the tension elements are not arranged at the same height have to be, but also at different altitudes. In this way let yourself. For example, not only halve the buckling length of each strut, but even split into three.

Another, expedient embodiment of the subject matter of the invention also emerges from claim 10. In this case, the buckling length of each strut becomes halved. In addition, the tension element is only insignificant in terms of appearance. The in the longitudinal extension of the tension element last intersection with the struts are securely supported by the bent end sections.

Finally, another embodiment of an inventive device is based on claim 10 Lattice girder out, which has a strut mechanism with at least two transverse to the longitudinal direction of the girder having adjacent rows of struts.

The one arranged between the strut rows and with the struts of both Tension element connected in rows shortens the buckling length of the struts in both rows and thus increases the overall buckling strength of the truss considerably.

Embodiments of the invention are described below with reference to the drawing explained.

1 shows a schematic side view of a first embodiment of a truss, FIG. 2 is a schematic side view of a second embodiment a truss, FIG. 3 is a schematic side view of a third embodiment a truss, FIG. 4 is a schematic side view of a fourth embodiment of a truss, FIG. 5 shows a section through the embodiments of FIG. 1 to 3, and FIG. 6 shows a section through the embodiment of FIG. 4.

From Fig. 1 is a truss 1, in particular a lightweight truss, can be seen, which consists of an upper chord 2 and a lower chord 3 and parallel thereto is composed of a strut mechanism 4 connecting these.

The belts and the struts are expediently made of metal, Light metal or plastic molded profiles (rolled, extruded or drawn) made or made of wood. Especially with lightweight lattice girders that are characterized by a delicate structure is the buckling strength of the struts in the Struts 4 are often small, since their buckling length is relatively large.

In the embodiment according to FIG. 1, the strut mechanism 4 consists, for example from zigzag arranged Finzelstreben 5, of which in dash-dotted lines Lines that show the median lines. The nodes between ting the struts 5 and the straps 2, 3 are in the area of the gravity lines S of the straps.

The buckling length of each strut 5 is halved by a tension element 6, which runs through in the longitudinal direction of the carrier and with its ends 8, 9 on the lower chord 3 is anchored, namely in fastening points 12 and 13. In the designated 7 The points of intersection between the tension element 6 and the struts 5 are the struts 5 supported on the tension element 6, expediently welded.

Each strut 5 is in the area of the intersection 7 on the two adjacent crossing points 7 of the adjacent struts 5 tensile strength against buckling Supported in the longitudinal direction of the carrier. At the same time there is also the buckling of the struts from the carrier level prevented. The end sections labeled 10 and 11 of the tension element 6 are bent towards the lower chord 3, so that the last Struts are securely supported. There are no junctions at the crossing points designed as they are usually with the help of gusset plates and longer welds or tiieten are produced, but here it is a matter of simple support points of the tension element on the struts, which are particularly simple to manufacture.

Fig. 2 shows a second embodiment of a truss 1 ', which has the same struts as the truss 1 of Fig. 1. Different is only that each group of six individual struts 5 is assigned a tension element 6 t is that is connected to it in the crossing points 7, while its to the lower chord 3 bent ends 8 'and 9' are anchored there. over the entire length of the truss 1 'there are therefore several tension elements 6' arranged one behind the other.

A third embodiment of a truss 1 ″ is shown in FIG. 3 emerges. Here is a strut mechanism 4 'between the upper chord 2 and the lower chord 3 arranged in the form of sawtooth-like individual struts 14, 15. In the longitudinal direction of the girder Here, too, a tension element 6 ″ runs approximately in the middle of the distance between the upper chord and the lower chord, the ends 8 "and 9" of the lower chord 3 or is anchored to the upper chord 2. This type of alternate anchoring is also therefore expediently so that the end 9 ″ of the tension element on the right, for example in FIG. 3 6 "does not have to be anchored to the lower chord 3 where the node of the last supported strut is formed.

In Fig. 4 is a further embodiment of a truss 1 '' ' shown, in which between the upper belt 2 'and the lower belt 3' two side by side lying rows of struts 16 and 17 are arranged, each X-shaped cross over. Here, too, a tension element 6 '' 'runs at approximately half the height in the longitudinal direction of the truss 1 through which in the crossing points 7 with the struts 16, 17 in the strut mechanism 4 "is connected.

Fig. 6 shows a section through the truss 1? '? of Fig. 4, that the tension element 6 '' 'lies in the space between the strut rows 16, 17 and is connected to the struts of both rows.

FIG. 5 shows a section through the embodiments of FIG. 1 to 3 and highlights how the Zugelemnt 6, 6 'or 6 "with the struts 5 or 14, 15 is connected.

Channel particularly simple type of connection is that in the Struts 5, 14, 15 passages 18 in the form of single multiple holes are provided through which the tension element is pushed. The tension element can be a round bar or a square bar. Use is also conceivable a hollow profile as a tension element.

To halve the buckling length of the struts 5, 14, 15 it is sufficient when the pulling element 6 is held in the passages 18 in a slightly sliding fit is because with a slight deformation of the strut there is already a toothing the tension element results, which prevents an actual buckling of the strut. However, the tension element is expediently in the passages 18 with the struts welded.

An alternative embodiment is shown in FIG. 5 in dashed lines indicated. Either on one or on both outer sides of the struts 5, 14, 15 can namely also run along a Zugelemnt, which then expediently by welding connected to the struts.

In Fig. 6 it is further indicated in dashed lines that in each strut row 16, 17 passages 18 'are provided, through which a each responsible for a row pulling element 6, 6 'or 6 "pushed through and, if necessary, welded in.

It is also conceivable that there are several between the upper belt and the lower belt Tension elements attached at different heights and supported on the struts will.

It is also conceivable to use so-called lattice girders Wire material to provide such tension elements that the strut snake or strut snakes from bent wire or from individual wire sections with regard to their resistance to buckling stiffen as previously explained.

Claims (11)

Truss patent claims 1. Truss, in particular lightweight truss, with upper and lower chords that are connected to each other by a strut system, characterized in that at least one in the longitudinal direction of the carrier Pulling element (6, 6 ', 6 ", 6') is provided, which with its ends (8, 9; 8th', 9 '; 8 ", 9") anchored in a tensile manner and place in its intersection (7) with the struts (5, 1h, 15, 16, 17) of the strut mechanism (4, 4 ', 4 ") transferring force to the struts is supported. 2. Truss according to claim 1, characterized in that g ek e n n z e i c h n e t that the tension element (6, 6 ', 6 ", 6"') at the points of intersection with the struts is welded. 3 truss according to claim 1, characterized by g ek e n n n z e i c h n e t that the ends (8, 9) of the tension element (6, 6 ') either on the upper belt (2) or on Lower chord (3) are anchored. 4. Truss according to claim 1, characterized in that g ek e n n z e 1 c h n e t that one end (8 ") of the tension element (6") on a belt and the other end (9 ") is anchored to the other strap. 5. Lattice girder according to claims 1 to 4, thereby g e k e n n It is clear that several anchored at both ends along the length of the beam Tension elements (6 ') are arranged one behind the other, and that each tension element (6 ') is supported on a certain number of struts (5). 6. Lattice girder according to claims 1 to 5, thereby g e k e n n z e i c h n e t that the tension element is a solid or hollow profile rod. 7. Lattice girder according to claims 1 to 6, thereby g e k e n n z e i chlln e t that the tension element (6) through passages (18, 18 ') in the struts (5, 16, 17) is. 8. Lattice girder according to claims 1 to 6, thereby g e k e n n z e i ch n e t that the tension element (6) each on an outside of a strut (5) is attached. 9. Truss according to claims 1 to 6 and 8, thereby g e k It is noted that there is a tension element on each of the two outer sides of the struts (5) (6) is attached. 10. Lattice girder according to claims 1 to 9, thereby g e k e n n z ei c h n e t that the tension element (6, 6 ', 6 ", 6"') in the middle between the Upper chord and the lower chord and runs parallel to this and according to its respectively last support point on a strut to the upper chord or lower chord is bent (End sections 11, 10). 11. Truss according to the preceding claims, with a strut mechanism, in which at least two rows of struts lying next to one another transversely to the longitudinal direction of the carrier are arranged, characterized in that between two rows of struts (16, 17) a tension element (6 "') connected to the struts of both rows is provided is.